The Mass-Energy Equivalence Calculator is a tool used to determine the energy produced or required based on a given mass using Albert Einstein's famous equation: E = m * c^2.
Formula of Mass-Energy Equivalence Calculator
The formula for calculating energy (E) using mass (m) and the speed of light in a vacuum (c) is as follows:
E = m * c^2
Where:
- E represents the energy in joules.
- m is the mass in kilograms.
- c is the speed of light in a vacuum, approximately 299,792,458 meters per second (m/s).
This formula, derived from Einstein's theory of relativity, showcases the relationship between mass and energy, illustrating that mass and energy are interchangeable.
Table of General Terms and Conversions
Search Term | Description |
---|---|
Mass-Energy Equivalence | Explanation of the relationship between mass and energy based on Einstein's theory of relativity. |
Energy in Joules | Definition and examples of energy measured in joules. |
Mass in Kilograms | Explanation and common examples of mass in kilograms. |
Speed of Light | Definition and significance of the speed of light in a vacuum. |
Adding a table of general terms helps users understand fundamental concepts related to mass, energy, and the speed of light. This table aids in simplifying complex terms and assists users in grasping the basics without the need for frequent calculations.
Example of Mass-Energy Equivalence Calculator
Suppose you have a mass of 2 kilograms. Using the Mass-Energy Equivalence Calculator, applying the formula E = m * c^2, we can calculate the energy produced.
Given:
- Mass (m) = 2 kilograms
- Speed of Light (c) = 299,792,458 m/s
Calculating: E = 2 kg * (299,792,458 m/s)^2 E ≈ 1.8 × 10^17 joules
This example demonstrates how the calculator determines energy output based on mass and the speed of light, providing an understanding of the immense energy equivalent to a small amount of mass.
Most Common FAQs
The equation reveals the relationship between mass and energy, explaining that mass can be converted into energy and vice versa, leading to groundbreaking discoveries in physics and energy production.
While the equation is fundamental in theoretical physics, its direct application in everyday scenarios is limit. However, it underpins various technological advancements and our understanding of the universe.
The equation emerged from Albert Einstein's theory of relativity in 1905, reshaping our understanding of space, time, and energy, paving the way for modern physics.